Expandable container having lid for providing headspace control in a food can

ABSTRACT

Expandable containers having lids for providing headspace control in food can are disclosed. In one embodiment, a process for producing a lid closure for cans containing foodstuff, the lid providing tightness during sterilization or pasteurization in a continuous autoclave, said cans being closed with a can closure may include (1) producing the can closure from an annular ring adapted for seaming to the can body and a lid panel having an outer ring band sealingly affixed onto an inner flat web; and (2) reshaping a central area of the lid panel by deep drawing to a smooth bowl shape or a dome shape with a plane surface, as original shape, a material of this central area thereby solidified or hardened to such an extent that under an increased pressure in a headspace of the can during a passage thereof through an autoclave station, the central area changes to an axially outwardly bulged shape that is mirror-inverted with respect to the original shape and, during a subsequent cooling of the can, the central area automatically returns substantially to the original shape thereof. The reshaping may be done prior to attaching the lid to the filled can, and the lid pane may be limited by an outer ring band.

RELATED APPLICATIONS

This patent application is a Divisional of U.S. patent application Ser.No. 12/162,923, filed Feb. 9, 2009, now U.S. Pat. No. ______, whichclaims priority the disclosure of which is hereby incorporated byreference in its entirety

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to lids for cans for receiving foodstuff, whichare to be subjected to a thermal treatment above 50° C. in the form ofsterilization or at least pasteurization. Methods for the production ofthe lids and for securing the leak tightness of the sealing are alsocovered.

2. Description of the Related Art

Lids are concerned having an annular ring for seaming to the can body,the lid can be firmly and tightly connected with the can body rim and isin particular made from metal, and a “lid diaphragm” (diaphragm orpanel) in the form of a cover surface which is affixed to the annularring (for seaming to the can body) in such a way that, for the openingof the can, the panel can be pulled off from the seamable annular ringor may be peeled off from it by means of pulling. This relates on theone hand to peeling foils and, on the other hand, also to foils whichare to be torn at the edge or are to be further torn.

Various designs of such lid covers are known, see U.S. Pat. No.4,211,338 (Bublitz). Difficulties with these lids arise at hightemperatures, at any rate above 50° C., as they are—as a rule—present insterilization or pasteurization processes in continuous autoclaves(retorts). The lid will leak or the lid diaphragm even begins to detachitself from the annular ring under the action of a difference inpressure which acts upon the lid, or can be damaged in such a way thatthis would result in a later leakage at the sealing line.

Consequently, these cans are mostly sterilized in such autoclaves (batchretort stations) which are equipped with means for generating an outerair or vapor pressure in order to apply a sufficient counter-pressureonto an outer surface of the lid, opposing the internal pressure in theclosed can, due to which the lid, in particular the lid diaphragm, willbe protected against too high differences in pressure AP.

It is not possible or requires great effort to equip “continuousautoclaves” with such counter-pressure means that are suitable forcontinuous passage.

Continuous autoclaves (for a pasteurization or a sterilization process)with a counterpressure due to a vapour atmosphere certainly generate alow permanent counterpressure on the lid surface of up to 1.6 bar (0.16MPa), but they are not sufficient for stabilizing customary “peel lids”without damage.

In addition to this, the lid surface does not form any smooth,fine-looking surface after cooling of the cans, which impairs acceptanceby the customers and results in illegibility of any type of inscriptionsor bar codes by scanners.

SUMMARY OF THE INVENTION

It is an object of the invention, to remedy this by a lid of this peeltype which allows a safe sterilization of filled and closed cans incontinuous autoclaves (high temperature prevailing there and a resultanthigh pressure in the can) without the risk of the breaking, breaking upor detaching of a plane (surface oriented) cover panel on or from theseamable annular ring.

After the cooling of the can, the lid is also to have an acceptableappearance.

These objects is attained concerning the lid.

The invention also comprises steps for “ensuring” the tightness of thecan closures during sterilization in a continuous autoclave in the senseof a securing or providing of tightness on the can closures that workwith an “annular ring” (for seaming to the can body). Productionprocesses for the can closure are disclosed.

The invention is not limited to lids for cans of a circularcross-section, but can also be applied with the same effect and the sameadvantages to cans of other circumferential or cross-sectional shapessuch as oval, rectangular, rectangular with rounded corners or squareshapes of cans (can bodies).

The “dome- or bowl-shaped preformation” (or deformation) of the coverpanel allows—after filling with food or foodstuff and upon closing ofeach can with the lid—to substantially reduce the headspace in the cansince the curved shape with its centre projects substantially downwardsbeyond that area of the annular ring that is placed innermost of a canbody inside. If, under the internal pressure formed during the thermalheating in the interior of the can, the dome- or bowl-shaped panelportion then changes, in particular abruptly changes, to a bulgingposition that is mirror-inverted to the original position, now towardsthe outside, resulting in a substantial enlargement of the headspace andthus a reduction of the pressure in the can formed during thermaltreatment.

This change function is supported by a stiffening of the cover panel atleast in the central portion by the preformation of this portion. Aplane material is used for this purpose, which itself or a layer thereofwill get harder due to the deep-drawing process. Thus, a certain shapekeeping hardness or stability results from this as a tightening. Saidstability is distributed across the entire panel surface, radiallywithin the annular ring. The panel surface is named plane or “arealoriented” as the surface has a lateral extension but on a curved panel,that is plane, but not flat.

This stability achieves that practically the same, but reversed orinverted panel shape is obtained upon outwards directed bulging. Itcorresponds to the inverted original dome shape without increasing thesurface area, without plastic preformation, in particular without a“stretching” of the panel. After the temperature is reduced, the centralportion of the cover panel is again returned to its preformed originalshape upon cooling, which it adopts without any further help (due to thevacuum formed in the inner space and “under the panel”).

The smooth dome or bowl shape (preformed bulging) of the lid of the canthat is ready for sale is very fine-looking and does not encounter anyproblems as regards acceptance by customers.

The process is for producing a lid closure for cans containingfoodstuff. The lid provides tightness during sterilization orpasteurization in a continuous autoclave. Said cans being closed with acan closure as lid. The can closure is produced from an annular ring(adapted for seaming to the can body, a so called “Deckelring”) and alid panel having an outer ring band. The band is sealingly placed ontoan inner flat web. Prior to attaching the lid to the filled can acentral area of the lid panel is reshaped by deep drawing to a smoothbowl shape or a dome shape with a plane surface, this as “originalshape”. An outer ring band limits the central area (surrounds it in caseof a circular lid). A material of this central area is solidified orhardened by the deep drawing process (step), this to such an extent thatunder an increased pressure in a headspace of the can during the can'spassage through an autoclave station, the central area changes to anaxially outwardly bulging shape that is mirror-inverted. The inversionis with respect to the “original shape”. During a subsequent cooling ofthe closed can, the central area automatically returns to the “originalshape”. This is at least substantially the same.

The claimed lid permits a sterilization or pasteurization of the filledcans at the pertinent high temperatures and differential pressures incontinuous autoclaves readily and without any risks, i.e. without anymeasure for generating a counter-pressure that additionally acts fromthe outside (other than the steam pressure). The steam pressure (vaporpressure) is regularly present, higher than atmospheric pressure, butnot high enough to support forces on the outer surface of the lid.

The dimensions of the preformed shape (of the central portion) can beeasily adjusted to the diameter and the volume of the cans. Likewise,the inclination of the flat web of the annular ring for seaming to thecan body to which the outer ring band of the panel is affixed isadjusted in such a way with respect to a horizontal plane that animaginary extension of the surface of the flat web extends at besttangentially to the dome- or inverted-bowl shaped central portion thatbulges outwardly under pressure. The inclination of the web is directedupwards; this is “outwards axially” when the can body is taken as areference, that is closed by the lid panel and the lid ring.

A preferred lid is adapted for closing a can with a diameter of 83 mm.The depth of the preformed lid panel is between 5 mm and 6 mm, approx.5,6 mm, the lowermost point of it being about 3 mm below the lowermostpoints of the annular ring for seaming to the can body. The bulgingcorresponds to a sphere segment in the case of a circular cross-sectionof the lid. The angle of the flat web is preferably between 22° and 25°with respect to the horizontal. Here, peeling forces are practicallycompletely avoided.

The smooth/plane bowl/dome surface of the preformed lid panel is notdisturbed by or interfered with any undulations or grooves.

The filled can with the lid can be at least pasteurized, in particulareven sterilized, in practically any of the known continuous autoclaveswithout additional counter-pressure means. The food in kept therein fora long time, resulting from thermal treatment

The production process of the lid closure is the subject matterdisclosed. The preformation (preforming) of the panel in the centralarea takes place in the same fashion. The processes permit the use ofalready used machines, in particular during a sealing on a plane flatweb with subsequent inclined deformation of the web upwards/outwards.The panel surface may be applied onto the already inclined flat web orthe—still plane—flat web which is to be inclined after heat sealing.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in greater detail in the following, usingschematic drawings and embodiments serving as examples.

FIG. 1 shows a section through a lid according to one example of theinvention.

FIG. 2 shows the transition area between annular ring for seaming to thecan body and lid diaphragm on a larger scale.

FIG. 3 shows a schematic sectional representation of a concrete exampleof a can with a predetermined diameter.

FIG. 4 shows a representation of a concrete example of a preformed lidpanel.

FIG. 5 shows a lateral view of a representation of the concrete example.

FIG. 6 2D sphere shape of a panel on a can body in theoreticalevaluation (no annular ring displayed).

FIG. 6a is a 2D sketch of FIG. 6.

FIG. 7 shows the 3D model of FIG. 6 a.

FIG. 7a is a 3D representation for explanation of force and tensilestress.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

As can be seen from FIG. 1, a lid 1 has an outer annular ring 2 suitablefor seaming to a can body and a lid panel 3.

The annular ring 2 (for seaming to the can body, in short: “lid ring”,seaming ring or “annular ring”) is e.g. made of sheet metal. Itcomprises an outer rim portion 4 as a “flared flange” for firm andliquid tight connection with a rim 24 of an opening of the can body, cf.FIG. 3. The flange 4 is connected through a core wall 5 with the flatweb 6 projecting generally radially inwards. The flat web 6 that extendsall around is axially outwardly inclined or tilted at an angle largerthan zero with respect to a horizontal plane that extends perpendicularto a vertical axis 8 of the lid 1. The radially inner edge of the flatweb 6 is axially bent towards the inside and is designed in a sterilefashion, in particular by means of a curling 7. It may also be replacedwith a relatively blunt inner edge. In the case of other can shapes, thelid shapes and the “annular ring” for seaming to the can body areaccordingly adapted (seen in the horizontal direction).

The lid panel 3 comprises an outer continuous ring band 3 a which atleast partially covers the flat web 6 of the annular ring from theoutside, if the panel 3 is tightly connected with the annular ring 2 ina fastening strip 13, e.g. by means of contact sealing or inductionsealing (pressure sealing, ultrasonic sealing, laser sealing). This ringband 3 a limits the central portion 3 b (provides its outer limit), atransition portion 3 c between the two being within the area of thecurling 7 after connection of the panel with the annular ring.

The central cover portion 3 b of the lid panel is preformed by adeep-drawing process. This process can be implemented prior to or afterthe connection of cover panel 3 and annular ring 2 in the fasteningstrip 13. The stabilizing reshaping only covers the central portion. Itis implemented across the entire surface of the panel.

The preforming converts the central portion 3 b into a dome or bowlshape in the axially inwards direction, the edge of the bowl is in thetransition portion 3 c to the outer ring band 3 a and the lowermostcentre 3 d of the panel is clearly, in particular at least a fewmillimeters below a horizontal plane 18 that passes through thelowermost points of the annular ring 2 according to FIG. 2. This alsocorresponds to the plane E2 of FIG. 3 in the example.

It is advantageous if, as is preferred, the panel itself comprises amaterial that is stiffened or hardened by the deep-drawing process suchas aluminum or the like, or contains at least such a layer. Due to this,the preformed central portion 3 b is provided with an inner shape (ordimensional) stability. This is of advantage for the entire appearanceof the finished, closed and thermally treated can package.

During sterilization, if temperature and consequently pressure aregenerated in the interior of the filled can that was closed with the lid(cf. also FIG. 3), the preformed central portion will change, inparticular change abruptly, from its “die sunk”, undulation-freedome/bowl shape to a practically mirror-inverted shape that is axiallyoutwardly bulging (sphere shaped in the case of round cans) as it isoutlined in a dash-dotted fashion at 3 b′ in FIG. 1 and FIG. 3.

Due to the stiffening or hardening of material of the cover panelachieved during the preforming, the dilatability of the central portion3 b is accordingly practically zero so that even in the case of highpressures formed in the can during (thermal) treatment in a continuousautoclave, the outwardly bulging shape of the central portion can bedetermined in advance (by means of a computing).

2-D Model.

FIG. 6 is a can with domed panel (pre shaped membrane) under internalpressure and cross section in FIG. 6a of the convex shaped panel. FIGS.6 and 6 a show the two-dimensional representation of a can with a domedpanel under internal overpressure. The two-dimensional model of thepre-shaped domed panel shows its convex shape under internalover-pressure P. The parameters which indicate the geometry are given inthe figures.

D is the diameter of the inner radius of the sealed zone, which isdifferent from the can diameter, h is the dome deflection, y and z arethe axes indicators, α is the angle of the dome with the y-axes. Thevolume increase, the angle and the radius of the convex dome can becalculated with the following equations:

${\Delta \; {V(h)}} = {{\frac{1}{6}\pi \; h^{3}} + {\frac{1}{8}\pi \; {{hD}^{2}\mspace{14mu}\left\lbrack {mm}^{3} \right\rbrack}}}$${\alpha \left( {y,h} \right)} = {{\sin \left( \frac{8{yh}}{D^{2} + {4h^{2}}} \right)}\mspace{14mu}\lbrack{rad}\rbrack}$${\rho (h)} = {\frac{{4h^{2}} + D^{2}}{8h}\mspace{14mu}\lbrack{mm}\rbrack}$

3-D Model.

FIG. 7 is a convex shaped domed panel in 3-D coordinate system having x,y and z; φ, Θ (Theta) and ρ (rho). FIG. 7a displays a force F on arandomly chosen small part (segment) of the domed panel and a partcross-section of it.

Stress in Domed Panel.

The tensile stress in the domed panel can be calculated rather straightforward with FIG. 7a using the force known from the multiplication ofthe pressure and the surface segment. The force has to be divided overthe length of the side (I) and the thickness (e) of the domed panel.

-   -   length1=πΔφsinΘ[mm]    -   thickness=e [mm]

The tensile stresses on all sides are therefore given by

$\sigma_{1} = {\sigma_{2} = {\sigma_{3} = {\sigma_{4} = {\frac{P\; \rho}{2e}\mspace{14mu}\left\lbrack \frac{N}{{mm}^{2}} \right\rbrack}}}}$

The radius of curvature of the domed panel can be expressed in candimension parameters.

The tensile stress in the domed panel is

$\sigma_{1} = {{P\frac{{4h^{2}} + D^{2}}{16e\; h}\mspace{14mu} \frac{N}{{mm}^{2}}}->{MPa}}$

In this equation . . .

-   -   P is the pressure [N/mm²]    -   p is the radius of the convex shaped domed panel    -   e is the domed panel thickness    -   h is the deflection of the domed panel    -   D is the inner radius of the sealed zone.

Slanted Sealed Zone (Sealing Strip).

The sealed zone can be “bended up” in such a way that the sealed zone isslanted upwards (axially outward, or upwards) and parallel to the domedpanel. In this situation there is only a shear stress in the sealed zoneand no longer a peel stress. The following relation between the tensilestress in the panel and the shear stress in the sealed zone applies

${\sigma e} = {\left. {\sigma_{s}w}\Rightarrow\sigma_{s} \right. = {\frac{e}{w}\sigma \mspace{14mu} {MPa}}}$

In this case the shear stress can be calculated by

$\begin{matrix}{\sigma_{s} = {\frac{F}{w} = {\frac{P\; \rho}{2\; w} = {P\frac{D^{2} + {4h^{2}}}{16{wh}}\mspace{14mu} {MPa}}}}} & \;\end{matrix}$

As outlined in FIG. 1, the depth 10 a of the bowl shape and the depth 10b of the bulging are practically equal. Referred to the plane 15, thevolume in the depth portion (defined by 10 a) is equal to the volume inthe depth portion (defined by 10 b). The depths/distances of the centersof the deformed lid panel represent the volume formed vis-à-vis thecentral plane 15 or E3. Upon the closing of a can body with the lid 1,the headspace H of the can is reduced by the dome/bowl volume (between15 and 3 b) and, upon heating during sterilization, the volume of theheadspace is enlarged by the total volume 12 (from depths 10 a and 10b).

Both contribute to a clear reduction of the maximally occurring pressureand secure the closed cans against damage upon their passage through theautoclave. Pressures of less than 1 bar (0.1 MPa) can be achieved,which, without the preforming of the panel would be clearly above thisvalue, e.g. at 1.5 bar (0.15 MPa). This amount of the achieved loweringof the pressure depends in general on the temperature of the foodstufffilled in. At hot filling of food the differential pressure that occursas a maximum on the panel is lower than the differential pressure whenusing cold filling such as for pet food as “foodstuff”.

The stability as to shape/form, i.e. the avoided permanent deformation(as a missing plastic deformation or—at most—a residual elasticdeformation by means of the modulus of elasticity) of the centralportion 3 b contributes to the fact that, upon the cooling of thefinished sterilized can, this preformed portion 3 b practically exactlyreadopts the original dome/bowl shape. In both conditions or positionsor according to panel shape 3 b and 3 b′ no undulations are contained inthe panel. The bowls or domes are smooth (also called bulged, but with aplane surface in the bulging).

The fact that the central portion retains its area (in an envelope)permits the advance calculation of the measure of its bulging in thecase of the pressures to be expected as a maximum during sterilizationso that the angle of inclination 11 of the flat web 6 of the annularring 2 for seaming to the can body can be adjusted to this right fromthe beginning. By no means is the angle smaller than the angle of atangent at the bulging of the central portion 3 b (next to the slantedweb). The angle 11 is rather selected larger with preference so thatthat—in the case of the maximum internal pressures formed in thecontinuous autoclaves—practically exclusively shear forces and nopeeling forces are active as resultant forces in the ring band 3 a ofthe panel 3 that is affixed to the flat web.

The angle 11 is set to more than 20° . The radius or the transversedimension (in the case of a deviation from the circular shape) of thecentral portion is shown as 9. Reference 16 in FIG. 2 emphasizes thatthe portion 3 b in its bowl shape projects down to clearly below theplane 18 which passes through the lowermost portions (or points) of theannular ring 2.

The dimensions of the preforming and that of the angle of inclinationdepend upon the volume and the radial dimensions of the can and thusalso on the size of the lid. The smaller the radius of the bulging in apressure-loaded condition is, the smaller is the mechanical stress inthe lid panel.

A suitable material of the lid panel 3 is a thin metal, preferably analuminum, which is used for the body diameter of 83 mm. Other diametersmay be used in the following manner, in a range of diameters betweensubstantially 50 mm and 100 mm (for Europe), in particular withespecially customary diameters: 73 mm, 99 mm, 65 mm, 83 mm; similar forcontainers (bodies) made of steel sheet.

The can body may be made of aluminum or steel sheet that are coveredwith a varnish.

The annular ring 2 is preferably made from an aluminum covered withvarnish, the outer varnish layer being a hot sealable sealing layer,which is sealingly connected with the annular ring in the sealingportion 13. Instead of metal the ring material may also be plasticmaterial or a plastic/metal composite, e.g. produced by means of aninjection process with or without an insert or with a previous insertingof the lid panel in the shaped opening for the ring. Annular rings madeof steel can likewise be used.

Instead of the hot sealable layer on the ring, ring 2 may also belaminated or extruded with polymers. The lamination of the ring is doneprior to the cutting out and the shaping of the annular ring.

In a preferred embodiment the lid panel that is connected with theannular ring (for seaming to the can body) preferably comprises severallayers:

-   -   coating varnish layer    -   print layer    -   aluminum layer (about 70 μm, in the range of 30 μm to 100 μm)    -   extruded polymer layer (material with approx. 12 g/m² to 30        g/m²)

The extruded polymer layer is a co-extruded layer of a tie layer and apeel layer. Other extrusions and laminations can likewise be used.

The lid panel 3 was reshaped (deep-drawn) to a convex shape in thecentral area 3 b as it is shown in FIG. 1 at 3 b. In the example, theconvex shape 3 b has a radius of 110 mm. The lid layer was sealinglyaffixed to an initially horizontal flat strip, in a connection area 13which is at first not upwardly inclined. The flat strip 6 of the ring 2,which supports the connection area was then upwardly deformed in orderto obtain the inclination position of the angle 11 of about 24° ,measured with respect to a horizontal plane 18/E2. This applies to thediameter of 83 mm of can and ring.

The sealing of the ring band 3 a of the lid panel 3 can be achieved moreeasily with a horizontal flat web 6 than with an already inclined flatweb. Consequently, the lid panel 3 may still not have any preformingshape of its own, but will only be provided with a correspondingpreformed shape after the sealing in the connection area 13 as sealingstrip. Here, the central area 3 b is preformed to a bowl shape by meansof the reshaping and stiffened or hardened, in order to admit hardly anyelastic deformation, but to be capable of changing to a practicallymirror-inverted, outwardly bulged bowl/dome shape in the case of aninner excess pressure. The central area is lowered that much below theplane 18 that there are several millimeters between the lowermost pointof the initial bowl shape 3 b and this plane (in the preformed state).

After the reshaping of the central area 3 b an upwardly directedreshaping of the flat strip 6 (or the web) can be carried out. Thisobtains its inclination of more than 20° in this connection.

In a preferred embodiment that is not depicted these two re-shapings,that of the bowl-shaped bulging of the lid panel with a hardening,stiffening character and that of providing an inclination of an annularpart the annular ring for seaming to the body, may also be carried outpractically at the same time.

In the example there was a sealing strip 13 as the connection area ofthe still not preformed lid panel 3 on the initially horizontallyoriented flat strip 6 of the ring, which was produced by implementing asealing with the following parameters

-   -   θ=190° C. temperature    -   P=150 kg Pressure    -   t=300 msec Sealing time.

The inwardly bulged bowl/dome shape had—as represented above—a maximumdeflection as the depth 10 a after the upwardly directed inclination ofthe flat web 6 which depth was between 5 mm and 6 mm, with a mean valueof about 5.6 mm within a probe of a plurality of tests.

FIG. 3 elucidates again the important advantages of the lid that iscapable of expansion.

The lid 23 is shown in its position after firmly and tightly fixed to acan body 20, which is filled with the foodstuff 21 and then closed. Asymbolic filling height is outlined at 22 or the level E1, above whichthe headspace H filled with air or vapor is located. The axis of the canis designated 25. The annular ring (for seaming to the can body) and thecan body rim are connected with each other in customary fashion by meansof a double seam 24 a at the end 24 of the container (represented in aseamed fashion on the left-hand side, and in a placed fashion on theright-hand side in FIG. 3). The connection area between the flat web ofthe annular ring and the ring band of the lid panel is designated 26.The central portion 27 a is deep-drawn in a dome/bowl-shaped fashion.Its depth 30 is represented exaggerated in order to display that itclearly reaches below the lowermost portion (plane E2) of the annularring for seaming to the can body. The bowl volume defined by its depth30 reduces the headspace H by the same volume, whereas the volumeallocated to the double arrow 31 and limited by the central portion inits concave dome/bowl and convex bulging shapes outlines the volumeenlargement of the headspace H with maximum pressure load ΔP duringthermal sterilization. The broken line extension 28 of the flat webmakes it clear that the angle of the flat web is larger than the angle11 of the tangent to the bulging 27 b.

A lid for a can with a diameter of 83 mm is assumed as a furtherpractical example. The dome/bowl depth 10 a/30 of the preformed lidpanel is between 5 mm and 6 mm, about 5.6 mm, the lowermost point 30 dof the bowl being about 3 mm below the lowermost points of the annularring. The bulging corresponds to a sphere portion—in the case of acircular cross—section of the lid as is shown by FIGS. 4 and 5. Theangle 11 is between 22° and 25° . Here, peeling forces are practicallycompletely avoided.

The reference symbols in FIGS. 4 and 5 are consistent with the ones usedbefore. FIG. 4 additionally shows a tab to pulling off the panel 3(having sealed ring band 3 b and central panel 3 a).

The smooth/plane dome/bowl surface is not disturbed by any undulationsor grooves. The can may be at least pasteurized, in particularsterilized with the lid in practically each of the known continuousautoclaves without counter-pressure means.

1-19. (canceled)
 20. A process for producing a lid closure for canscontaining foodstuff, the lid providing tightness during sterilizationor pasteurization in a continuous autoclave, said cans being closed witha can closure comprising: producing the can closure from an annular ringadapted for seaming to the can body and a lid panel having an outer ringband sealingly affixed onto an inner flat web; reshaping a central areaof the lid panel by deep drawing to a smooth bowl shape or a dome shapewith a plane surface, as original shape, a material of this central areathereby solidified or hardened to such an extent that under an increasedpressure in a headspace of the can during a passage thereof through anautoclave station, the central area changes to an axially outwardlybulged shape that is mirror-inverted with respect to the original shapeand, during a subsequent cooling of the can, the central areaautomatically returns substantially to the original shape thereof;wherein the reshaping is done prior to attaching the lid to the filledcan; and wherein the lid panel is limited by an outer ring band.
 21. Theprocess of claim 20, wherein the central area of the lid panel isdeep-drawn after the outer ring band is sealingly affixed to the flatweb of the annular ring.
 22. The process of claim 20, wherein the flatweb of the annular ring is upwardly re-shaped after the lid panel issealingly affixed to the flat web of the annular ring, wherein the flatweb is planar at sealing.
 23. The process of claim 21, wherein thelowering deep drawing of the lid panel and an upwards re-shaping of theflat web take place substantially at the same time.
 24. The process ofclaim 20, wherein the central area of the lid panel is deep-drawn priorto affixing the central area of the lid panel to the flat web of theannular ring.
 25. The process of claim 20, wherein the flat web isinclined when it is sealingly affixed.
 26. The process of claim 25,wherein an angle of inclination of the flat web is between about 20° andabout 30°.
 27. The process of claim 20, wherein the can has a diameterof about 83 mm, and an axial distance of the center of the central areapreformed in a bowl-shaped fashion is downwardly shifted due to thereshaping from a horizontal reference plane by between about 5 mm andabout 6 mm.
 28. The process of claims 20, wherein the ring band issealingly affixed to the flat web by hot sealing.
 29. The process ofclaim 20, wherein the solidification or hardening is distributed or actsacross substantially the entire central area. 30-38. (canceled)
 39. Theprocess of claim 27, wherein the axial distance of the center of thecentral area preformed in a bowl-shaped fashion is downwardly shifteddue to the reshaping from a horizontal reference plane by about 5.6 mm.40. The process of claim 28, wherein the hot sealing process is aninduction process.